Papermaking Clothing Defining a Width of a Paper Web and Associated System and Method
A clothing for supporting a wet paper web for dewatering is provided, comprising a dewatering fabric extending in a machine direction and formed only from a woven material to have a single, substantially consistent, permeability. A pair of laterally-spaced strip portions extend along the dewatering fabric in the machine direction, with each being substantially and consistently impermeable to air and forming a substantially and consistently smooth non-water-retaining surface. The strip portions define a permeable web-carrying portion of the dewatering fabric therebetween, wherein the paper web carried thereby extends over the entire width thereof. The permeable web-carrying portion allows air to flow therethrough, exclusively of the impermeable strip portions, such that the wet paper web carried only by the permeable web-carrying portion is dewatered. The width of the permeable web-carrying portion thereby defines the width of the wet paper web dried thereon. Associated systems and methods are also provided.
Latest Albany International Corp. Patents:
This application is a division of U.S. patent application Ser. No. 13/565,442 filed Aug. 2, 2012 which is a division of U.S. patent application Ser. No. 12/024,333 filed Feb. 1, 2008, now U.S. Pat. No. 8,241,464 granted Aug. 14, 2012, the entire disclosures of all are incorporated herein by reference.
BACKGROUND OF THE INVENTION1. Field of the Invention
Embodiments of the present invention are directed to a papermaking clothing and associated system and method for producing a defined-width paper web and, more particularly, to a through-air drying papermaking system and associated clothing and method implementing a through-air drying fabric having laterally-spaced impermeable strips such that the fabric therebetween defines the width of a paper web.
2. Description of Related Art
In a representative papermaking process, a fibrous slurry (i.e., an aqueous wood pulp or cellulose fiber mixture) is deposited on a moving forming wire from a headbox. The open structure of the forming wire allows some of the water from the slurry to drain therethrough, wherein the remaining cellulose fibers adhere to each other to form a fibrous web. Since the forming wire moves in a machine direction during the deposition of the fibrous slurry, an elongate wet paper web is formed. Further, a representative papermaking machine as shown, for example, in
In one edge trimming process, a high pressure water stream is directed through a water jet or nozzle toward the formed paper web as it is transported on the forming wire (i.e., the inner forming wire) in the machine direction, as shown, for example, in
In some papermaking processes, once the paper web has proceeded through the edge trimming process, it is then directed through a dewatering process, such as a drying process. In one such drying process, one or more through-air dryers (TADs) may be implemented to dry the web. A typical TAD includes a cylindrical roll (otherwise referred to herein as a “TAD cylinder”), wherein the shell defining the cylindrical roll is configured and structured so as to allow air to pass through the cylindrical shell, about which the paper web is at least partially wrapped during the drying process. A TAD further includes a hood configured to substantially encompass the roll of the TAD, wherein air is typically heated and directed from the hood and into the roll through the shell, or from the roll through the shell and into the hood. In any instance, the air is directed through the paper web wrapped about the roll to facilitate drying thereof. The paper web, when transported through the TAD, is typically supported by an endless web-carrying fabric (otherwise referred to herein as a “TAD fabric”). Thus, the air directed through the paper web must also pass through the TAD fabric.
In some instances, however, the TAD fabric for transporting the paper web through the TAD may be a costly part of the paper production process. For example, mechanical decide bands may be installed on the cylinder, in a laterally spaced apart relation, so as to define the “drying area” of the TAD. That is, such deckle bands may be, for example, impermeable strips of an impermeable material that are physically placed over the TAD cylinder at or about the edges/flanges thereof in order to block or re-direct air flow through the shell of the TAD cylinder. In such a configuration, the decide bands are installed on the TAD cylinder at two spaced-apart positions across the width of the roll, and the TAD fabric is further configured to laterally extend across the roll and over both deckle bands. The width of the TAD fabric between the deckle bands thus defines the drying area of the TAD, where a paper web up to that width can be dried by the TAD. One disadvantage with such deckle bands, though, is that the placement thereof with respect to the roll for defining the drying area can be difficult to determine with accuracy due to, for example, the thermal expansion behavior of the roll. As such, temporary deckle bands may initially be used, with such temporary decide bands being comprised of, for example, a polytetrafluoroethylene material, secured to the roll by temporary adhesives during set-up of the papermaking machine. This initial set-up, in some instances, may be costly in terms of the time and the trial-and-error resources needed to determine the appropriate positions of the deckle bands.
Once the appropriate positions of the temporary deckle bands are determined deckle bands for use in the long term papermaking process can be installed on the roll. Such decide bands may be comprised of a more durable material such as, for example, stainless steel, welded to the roll or the end rings thereof in the determined positions. However, one drawback of these metallic decide bands is that, under certain conditions, the deckle bands may cause corrosion of the roll or the end rings thereof. Further, these deckle bands installed on the roll may be difficult to clean under/around. Also, between the initial set-up and actual (long term) production, machine parameters may be altered which may, in turn, change the requirements for the deckle bands. As such, the decide bands may not be installed until immediately prior to production, which may result in delays and/or scheduling issues as a result of their implementation. As a result, the installation of the deckle bands for the long term papermaking process may also be costly in terms of time and resources.
In papermaking machines implementing a TAD having decide bands affixed to the TAD roll, the paper web dried thereby is typically transferred to the TAD fabric or clothing such that there is an open lateral gap of the fabric between each edge of the paper web and the respective adjacent decide band as shown, for example, in
In order to address/minimize fabric degradation, some papermaking machines implement various fabric edge protection measures such as, for example, air knife edge cooling as shown, for example, in
In some instances, a water spray edge protection system (see, e.g., U.S. Pat. No. 6,314,659) may also be implemented, as shown in
Some existing devices and methods for addressing the fabric gap about each lateral edge of a paper web in a TAD papermaking machine thus may not provide a simple and effective method of changing the width of a paper web capable of being processed by the papermaking machine since the width of the paper web may often be determined by “permanently-installed” TAD deckle bands (or “deckles”). Further, efforts to address the fabric gap, as discussed above, may often be energy and resource inefficient (i.e., high energy consumption due to, for example, poor heat transfer and removal of water brought into the TAD by the fabric), and may overall be less than particularly effective for the intended purpose.
Thus, there exists a need for a system, apparatus and method for determining a width of a paper web in a papermaking machine, particularly a TAD papermaking machine in a process-effective manner. A solution should desirably involve minimal equipment, should be relatively simple and cost effective, should be capable of being readily altered for different web widths without extensive set up and testing requirements, and should facilitate maintenance of the papermaking machine. Such a solution should also desirably provide protection for the fabric gap of the drying fabric so as to prevent or minimize premature degradation thereof, while addressing energy consumption issues such as the amount of water brought into the TAD by the drying fabric, and a more complete and effective use of the heated air used in the TAD for drying the paper web.
BRIEF SUMMARY OF THE INVENTIONThe above and other needs are net by embodiments of the present invention which, according to one aspect, provides a papermaking clothing configured to support a wet paper web for dewatering and/or drying. Such a clothing comprises an endless web-carrying fabric formed only from a woven material so as to have a single, substantially consistent, permeability, wherein the web-carrying fabric defines a machine direction and has opposed lateral edges. A pair of laterally spaced apart strip portions extend along the web-carrying fabric in the machine direction, wherein each strip portion is substantially and consistently impermeable to air and has a substantially and consistently smooth surface adapted to not retain water, wherein the strip portions define a permeable portion of the web-carrying fabric therebetween. The permeable portion of the web-carrying fabric is adapted such that the wet paper web supported thereby extends over an entire width thereof. The permeable portion of the web-carrying fabric is thereby configured to allow air directed thereat to flow therethrough, exclusively of the impermeable strip portions, such that the wet paper web supported only by the permeable portion of the web carrying fabric is dewatered, wherein the width of the permeable portion of the web-carrying fabric between the impermeable strip portions defines a width of the wet paper web being dewatered thereon.
That is, one aspect of the present invention comprises:
A papermaking clothing configured to support a wet paper web for dewatering, said clothing comprising:
-
- an endless web-carrying fabric formed only from a woven material so as to have a single, substantially consistent, permeability, the web-carrying fabric defining a machine direction and having opposed lateral edges; and
- a pair of laterally spaced apart strip portions extending along the web-carrying fabric in the machine direction, each strip portion being substantially and consistently impermeable to air and haying a substantially and consistently smooth surface adapted to not retain water, the strip portions defining a permeable portion of the web-carrying fabric therebetween, the permeable portion being adapted such that the wet paper web supported thereby extends over an entire width thereof, whereby the permeable portion is configured to allow air directed thereat to flow therethrough, exclusively of the impermeable strip portions, such that the wet paper web supported only by the permeable portion is dewatered, the width of the permeable portion between the impermeable strip portions thereby defining a width of the wet paper web being dewatered.
Another aspect of the present invention provides a system for drying a wet paper web, comprising at least one through-air dryer having a cylinder defined by a shell configured so as to allow air to pass therethrough. The cylinder is further configured to rotate in a machine direction. An endless drying fabric is formed only from a woven material so as to have a single, substantially consistent, permeability. The drying fabric defines a machine direction, has opposed lateral edges, and is wrapped about at least a portion of the cylinder. The drying fabric further includes a pair of laterally spaced apart strip portions extending along the drying fabric in the machine direction, wherein each strip portion is substantially and has a substantially and consistently smooth surface adapted to not retain water. The strip portions define a web-carrying portion of the drying fabric therebetween. The web-carrying portion of the drying fabric is configured such that the wet paper web supported thereby, on a web-side surface thereof, extends over an entire width thereof, whereby the web-carrying portion of the drying fabric is configured to allow air directed thereat by the at least one through-air dryer to flow therethrough, exclusively of the strip portions, such that the wet paper web supported only by the web-carrying portion of the drying fabric is dried. The width of the web-carrying portion of the drying fabric between the strip portions thereby defines a width of the wet paper web being dried by the at least one through-air dryer.
That is, another aspect comprises:
A system for drying a wet paper web, comprising:
-
- at least one through-air dryer including a cylinder defined by a shell configured so as to allow air to pass therethrough, the cylinder being further configured to rotate in a machine direction; and
- an endless drying fabric formed only from a woven material so as to have a single, substantially consistent, permeability, the drying fabric defining a machine direction, having opposed lateral edges, and being wrapped about at least a portion of the cylinder, the drying fabric further including a pair of laterally spaced apart strip portions extending along the drying fabric in the machine direction, each strip portion being substantially and consistently impermeable and having a substantially and consistently smooth surface adapted to not retain water, the strip portions defining a web-carrying portion of the drying fabric therebetween, the web-carrying portion being configured such that the wet paper web supported thereby, on a web-side surface thereof extends over an entire width thereof, whereby the web-carrying portion is configured to allow air directed thereat by the at least one through air dryer to flow therethrough, exclusively of the strip portions, such that the wet paper web supported only by the web-carrying portion is dried, the width of the web-carrying portion between the strip portions thereby defining a width of the wet paper web being dried by the at least one through-air dryer.
A further aspect of the present invention provides a method of dewatering a wet paper web. Such a method comprises carrying a wet paper web in a machine direction with an endless web-carrying fabric formed only from a woven material so as to have a single, substantially consistent, permeability. The web-carrying fabric has opposed lateral edges and further includes a pair of laterally spaced apart strip portions extending along the web-carrying fabric in the machine direction, wherein each strip portion is substantially and consistently impermeable and has a substantially and consistently smooth surface adapted to not retain water. The impermeable strip portions define a permeable portion of the web-carrying fabric therebetween. The permeable portion of the web-carrying fabric is further configured such that the wet paper web carried thereby extends over an entire width thereof. Air is then directed toward the web-carrying fabric, wherein the permeable portion of the web-carrying fabric is configured to allow the air to flow therethrough, exclusively of the impermeable strip portions, such that the wet paper web carried only by the permeable portion of the web-carrying fabric is dried. The width of the permeable portion of the web-carrying fabric between the impermeable strip portions thereby defines a width of the wet paper web being dewatered on the web-carrying fabric.
That is, another aspect comprises:
A method of dewatering a wet paper web, comprising:
-
- carrying a wet paper web in a machine direction with an endless web-carrying fabric formed only from a woven material so as to have a single, substantially consistent, permeability, the web-carrying fabric having opposed lateral edges and further including a pair of laterally spaced apart strip portions extending along the web-carrying fabric in the machine direction, each strip portion being substantially and consistently impermeable and having a substantially and consistently smooth surface adapted to not retain water, the impermeable strip portions defining a permeable portion of the web-carrying fabric therebetween, the permeable portion being configured such that the wet paper web carried thereby extends over an entire width thereof, and
- directing air toward the web-carrying fabric, the permeable portion thereof being configured to allow the air to flow therethrough, exclusively of the impermeable strip portions, such that the wet paper web carried only by the permeable portion is dewatered, the width of the permeable portion between the impermeable strip portions thereby defining a width of the wet paper web being dewatered on the web-carrying fabric.
Another aspect of the present invention provides a method of determining a width of a paper web. Such a method comprises transporting a wet paper web on a forming wire in a machine direction toward an endless dewatering and/or embossing fabric having a permeable web-carrying portion, wherein the wet paper web is formed on the forming wire so as to be wider than the permeable web-carrying portion of the fabric. The embossing and/or paper web structuring fabric is formed only from a woven material so as to have a single, substantially consistent, permeability, wherein the fabric further includes opposed lateral edges and a pair of laterally spaced apart strip portions extending along the fabric in the machine direction. Each strip portion is substantially and consistently impermeable and has a substantially and consistently smooth surface adapted to not retain water. The impermeable strip portions thereby define the permeable web carrying portion of the fabric therebetween. The wet paper web is then engaged with the dewatering and/or embossing fabric such that only the permeable web-carrying portion of the fabric receives the wet paper web, exclusively of the impermeable strip portions, thereby trimming the wet paper web to the width of the permeable web-carrying portion of the fabric such that the wet paper web extends over an entire width of the permeable web-carrying portion of the fabric.
That is, another aspect comprises:
A method of determining a width of a paper web, comprising:
-
- transporting a wet paper web on a forming wire in a machine direction toward an endless fabric having a permeable web-carrying portion, the wet paper web being formed on the forming wire so as to be wider than the permeable web-carrying portion of the fabric, the fabric being formed only from a woven material so as to have a single, substantially consistent, permeability, the fabric further including opposed lateral edges and a pair of laterally spaced apart strip portions extending along the fabric in the machine direction, each strip portion being substantially and consistently impermeable and having a substantially and consistently smooth surface adapted to not retain water, the impermeable strip portions thereby defining the permeable web-carrying portion of the fabric therebetween; and
- engaging the wet paper web with the fabric such that only the permeable web-carrying portion of the fabric receives the wet paper web, exclusively of the impermeable strip portions, thereby trimming the wet paper web to the width of the permeable web-carrying portion such that the wet paper web extends over an entire width of the permeable web-carrying portion.
Yet another aspect of the present invention provides a method of processing a paper web. Such a method comprises carrying a paper web in a machine direction with an endless fabric, formed only from a woven material so as to have a single, substantially consistent, permeability, wherein the fabric has opposed lateral edges and further includes a pair of laterally spaced apart strip portions extending along the fabric in the machine direction. Each strip portion is substantially and consistently impermeable, and has a substantially and consistently smooth surface adapted to not retain water. The impermeable strip portions thereby define a permeable web-carrying and structuring portion of the fabric therebetween. The permeable web-carrying portion of the fabric is configured such that the paper web carried thereby extends over an entire width thereof. Air is then directed toward the fabric so as to dewater and/or emboss the paper web to obtain an increased dryness and bulk, wherein the permeable web-carrying portion of the fabric is configured to allow the air to flow therethrough, exclusively of the impermeable strip portions, such that the paper web carried only by the permeable web-carrying portion of the fabric is processed. The width of the permeable web-carrying and structuring portion of the fabric between the impermeable strip portions thereby defines a width of the paper we being processed on the fabric. in such instances, the paper web may be processed, for example, by a vacuum device which applies suction to the paper web, by a molding device which molds or embosses the paper web according to the fabric topography such that the web hulk increases, and/or a through-air drying device which dries the paper web.
That is, another aspect comprises:
A method of processing a paper web, comprising:
-
- carrying a paper web in a machine direction with an endless fabric formed only from a woven material so as to have a single, substantially consistent, permeability, the fabric having opposed lateral edges and further including a pair of laterally spaced apart strip portions extending along the fabric in the machine, each strip portion being substantially and consistently impermeable and having a substantially and consistently smooth surface adapted to not retain water, the impermeable strip portions defining a permeable web carrying portion of the fabric therebetween, the permeable web carrying portion being configured such that the paper web carried thereby extends over an entire width thereof; and
- directing air toward the fabric so as to process the paper web, the permeable web-carrying portion thereof being configured to allow the air to flow therethrough, exclusively of the impermeable strip portions, such that the paper web carried only by the permeable web-carrying portion is processed, the width of the permeable web-carrying portion between the impermeable strip portions thereby defining a width of the paper web being processed on the fabric.
Still another aspect of the present invention provides a method of protecting a through-air drying fabric carrying a paper web. Such a method comprises carrying a paper web in a machine direction with an endless fabric formed only from a woven material so as to have a single, substantially consistent, permeability, wherein the fabric has opposed lateral edges and further includes a pair of laterally spaced apart strip portions extending along the fabric in the machine direction. Each strip portion is substantially and consistently impermeable, and has a substantially and consistently smooth surface adapted to not retain water. The strip portions define a web-carrying portion of the fabric therebetween, wherein the web-carrying, portion of the fabric is configured such that the paper web carried thereby extends over an entire width thereof. High temperature air is then directed toward the fabric such that the air flows through the web-carrying portion of the fabric, exclusively of the strip portions, and interacts with the web-carrying portion only where the paper web is carried thereby. The paper web extending across the entire width of the web-carrying portion thereby protects the web carrying portion of the fabric from the high temperature air.
That is, another aspect comprises:
A method of protecting a through-air drying fabric carrying a paper web, comprising:
-
- carrying a paper web in a machine direction with an endless fabric forme only from a woven material so as to have a single, substantially consistent, permeability, the fabric having opposed lateral edges and further including a pair of laterally spaced apart strip portions extending along the fabric in the machine direction, each strip portion being substantially and consistently impermeable and having a substantially and consistently smooth surface adapted to not retain water, the strip portions defining a web-carrying portion of the fabric therebetween, the web-carrying portion being configured such that the paper web carried thereby extends over an entire width thereof; and
- directing high temperature air toward the fabric such that the air flows through the web-carrying portion, exclusively of the strip portions, and interacts with the web-carrying portion only where the paper web is carried thereby, the paper web extending across the entire width of the web-carrying portion thereby protecting the web-carrying portion of the fabric from the high temperature air.
Another aspect of the present invention further provides a method of changing a width of a paper web within a single papermaking machine. Such a method comprises transporting a wet paper web on a forming wire in a machine direction toward a first endless fabric having a first permeable web-carrying portion, wherein the wet paper web is formed on the forming wire so as to be wider than the first permeable web-carrying portion of the first fabric. The first fabric is formed only from a woven material so as to have a single, substantially consistent, permeability, wherein the first fabric further includes a pair of laterally spaced apart first strip portions extending along the first fabric in the machine direction, with each of the first strip portions being substantially and consistently impermeable, and having a substantially and consistently smooth surface adapted to not retain water. The first impermeable strip portions thereby define the first permeable web-carrying portion of the first fabric therebetween. The wet paper web transported by the forming wire is then engaged with the first fabric such that the first permeable web-carrying portion of the first fabric receives the wet paper web, and such that the wet paper web extends over an entire width of the first permeable web-carrying portion of the first fabric, exclusively of the first strip portions, so as to trim the wet paper web to the width of the first permeable web-carrying portion of the first fabric.
The first fabric is then replaced with a second endless fabric formed only from a woven material so as to have a single, substantially consistent, permeability. The second fabric further includes a pair of laterally spaced apart second strip portions extending along the second fabric in the machine direction, with each of the second strip portions being substantially and consistently impermeable, and having a substantially and consistently smooth surface adapted to not retain water. The second impermeable strip portions thereby define a second permeable web-canying portion of the second fabric therebetween. The wet paper web transported by the forming wire is then engaged with the second fabric such that the second permeable web-carrying portion of the second fabric receives the wet paper web, and such that the wet paper web extends over an entire width of the second permeable web-carrying portion of the second fabric, exclusively of the second impermeable strip portions. The second permeable web-carrying portion of the second fabric has a different width than the first permeable web-carrying portion of the first fabric, and is narrower than the wet paper web formed on the forming wire, so as to trim the wet paper web to the width of the second permeable web-carrying portion of the second fabric.
That is, another aspect comprises:
A method of changing a width of a paper web within a single papermaking machine, comprising:
-
- transporting a wet paper web on a forming wire in a machine direction toward a first endless fabric having a first permeable web-carrying portion, the wet paper web being formed on the forming wire so as to be wider than the first permeable web-carrying portion of the first fabric, the first fabric being formed only from a woven material so as to have a single, substantially consistent, permeability, the first fabric further including a pair of laterally spaced apart first strip portions extending along the first fabric in the machine direction, each of the first strip portions being substantially and consistently impermeable and having a substantially and consistently smooth surface adapted to not retain water, the first impermeable strip portions thereby defining the first permeable web-carrying portion of the first fabric therebetween;
- engaging the wet paper web transported by the forming wire with the first fabric such that the first permeable webcarrying portion of the first fabric receives the wet paper web and such that the wet paper web extends over an entire width of the first permeable web-carrying portion, exclusively of the first impermeable strip portions, so as to trim the wet paper web to the width of the first permeable web-carrying portion;
- replacing the first fabric with a second endless fabric formed only from a woven material so as to have a single, substantially consistent, permeability, the second fabric further including a pair of laterally spaced apart second strip portions extending along the second fabric in the machine direction, each of the second strip portions being substantially and consistently impermeable and having a substantially and consistently smooth surface adapted to not retain water, the second impermeable strip portions thereby defining a second permeable web-carrying portion of the second fabric therebetween; and
- engaging the wet paper web transported by the forming wire with the second fabric such that the second permeable web-carrying portion of the second fabric receives the wet paper web and such that the wet paper web extends over an entire width of the permeable second web-carrying portion, exclusively of the second impermeable strip portions, the second permeable web-carrying portion having a different width than the first permeable web-carrying portion and being narrower than the wet paper web formed on the forming wire, so as to trim the wet paper web to the width of the second permeable web-carrying portion.
Still another aspect of the present invention comprises a method of forming a papermaking clothing, adapted to support a wet paper web for structuring, molding, or embossing, and/or for drying or dewatering, from an endless fabric formed only from a woven material so as to have a single, substantially consistent, permeability, with the fabric defining a machine direction and having opposed lateral edges. Such a method includes applying a self-leveling filler substance to the fabric at laterally spaced apart positions so as to form a pair of laterally spaced apart strip portions extending along the fabric in the machine direction. The self-leveling filler substance is then allowed to set such that each strip portion becomes substantially and consistently impermeable to air and forms a substantially and consistently smooth surface adapted to not retain water, whereby the strip portions define a web-carrying portion of the fabric therebetween.
That is, another aspect comprises:
A method of forming a papermaking clothing adapted to support a wet paper web for drying or dewatering, from an endless fabric formed only from a woven material so as to have a single, substantially consistent, permeability, the fabric defining a machine direction and having opposed lateral edges, said method comprising:
-
- applying a self-leveling filler substance to the fabric at laterally spaced apart positions so as to form a pair of laterally spaced apart strip portions extending along the fabric in the machine direction; and
- allowing, the self-leveling filler substance to set such that each strip portion becomes substantially and consistently impermeable to air and forms a. substantially and consistently smooth surface adapted to not retain water, whereby the strip portions define a web carrying portion of the fabric therebetween.
A further aspect of the present invention comprises a method of forming a papermaking clothing, adapted to support a wet paper web for drying or dewatering and/or molding and structuring, from an endless fabric formed only from a woven material so as to have a single, substantially consistent, permeability, with the fabric defining a machine direction and having opposed lateral edges. Such a method includes applying heat to the fabric at laterally spaced apart positions, wherein the heat is configured to cause the fabric at the laterally spaced apart positions to attain a material flow temperature. A pressure is applied to the fabric at the laterally spaced apart positions, substantially simultaneously with heating the fabric thereat to the material flow temperature, so as to form a pair of laterally spaced apart strip portions extending along the fabric in the machine direction, wherein each strip portion is substantially and consistently impermeable to air and forms a substantially and consistently smooth surface adapted to not retain water, and whereby the strip portions define a web-carrying portion of the fabric therebetween.
That is, another aspect comprises:
A method of forming a papermaking clothing adapted to support a wet paper web for drying or dewatering, from an endless fabric formed only front a woven material so as to have a single, substantially consistent, permeability, the fabric defining a machine direction and having opposed lateral edges, said method comprising:
-
- applying heat to the fabric at laterally spaced apart positions, the heat being configured to cause the fabric at the laterally spaced apart positions to attain a material flow temperature; and
- applying a pressure to the fabric at the laterally spaced apart positions, substantially simultaneously with heating the fabric thereat to the material flow temperature, so as to form a pair of laterally spaced apart strip portions extending along the fabric in the machine direction, each strip portion being substantially and consistently impermeable to air and forming a substantially and consistently smooth surface adapted to not retain water, whereby the strip portions define a web-carrying portion of the fabric therebetween.
Another aspect of the present invention comprises a system for dewatering, drying a wet paper web. At least one processing device is configured to provide a flow of air. An embossing or structural endless fabric is formed only from a woven material so as to have a single, substantially consistent, permeability. The fabric defines a machine direction, has opposed lateral edges, and is configured to interact with the at least one processing device. The fabric farther includes a pair of laterally spaced apart strip portions extending along the fabric in the machine direction, wherein each strip portion is substantially and consistently impermeable and has a substantially and consistently smooth surface adapted to not retain water. The strip portions define a web-carrying portion of the fabric therebetween, wherein the web-carrying portion is configured such that the wet paper web supported thereby, on a web-side surface thereof, extends over an entire width thereof, and whereby the web-carrying portion is configured to allow the air provided by the at least one processing device to flow therethrough and process the wet paper web, exclusively of the strip portions, such that the wet paper web supported only by the web carrying portion is at least one of dried and dewatered. The width of the web-carrying portion between the strip portions thereby defines a width of the wet paper web being processed on the fabric by the at least one processing device.
That is, another aspect comprises:
A system for dewatering or drying a wet paper web, comprising:
-
- at least one processing device configured to provide a flow of air; and
- an endless fabric formed only from a woven material so as to have a single, substantially consistent, permeability, the fabric defining a machine direction, having opposed lateral edges, and being configured to interact with the at least one processing device, the fabric further including a pair of laterally spaced apart strip portions extending along the fabric in the machine direction, each strip portion being substantially and consistently impermeable and having a substantially and consistently smooth surface adapted to not retain water, the strip portions defining a web-carrying portion of the fabric therebetween, the web-carrying portion being configured such that the wet paper web supported thereby, on a web-side surface thereof, extends over an entire width thereof, whereby the web-carrying portion is configured to allow the air provided by the at least one processing device to flow therethrough and process the wet paper web, exclusively of the strip portions, such that the wet paper web supported only by the web-carrying portion is at least one of dried and de watered, the width of the web-carrying portion between the strip portions thereby defining a width of the wet paper web being processed on the fabric by the at least one processing device.
A further aspect of the present invention comprises a papermaking clothing configured to support a wet paper web. Such a clothing includes an endless fabric formed only from a woven material so as to have a single, substantially consistent, permeability to air of between about 2.2 m/s and about 3.0 m/s, at a pressure of about 100 Pa and a temperature of about 20° C., wherein the fabric defines a machine direction and having opposed lateral edges. A pair of laterally spaced apart strip portions extend along the fabric in the machine direction, wherein each strip portion is substantially and consistently impermeable to air and has a substantially and consistently smooth surface adapted to not retain water. The strip portions define a web-carrying portion of the fabric therebetween, wherein the web-carrying portion is adapted such that the wet paper web supported thereby extends over an entire width thereof, and whereby the web-carrying portion is configured to allow air directed thereat to flow therethrough, exclusively of the strip portions, such that the wet paper web supported only by the web-carrying portion is exposed to the air. The width of the web-carrying portion between the strip portions thereby defines a width of the wet paper web being processed.
That is, another aspect comprises:
A papermaking clothing configured to support a wet paper web, said clothing comprising:
-
- an endless fabric formed only from a woven material so as to have a single, substantially consistent, permeability to air of between about 2.2 m/s and about 10 m/s, at a pressure of about 100 Pa and a temperature of about 20° C., the fabric defining a machine direction and having opposed lateral edges; and
- a pair of laterally spaced apart strip portions extending along the fabric in the machine direction, each strip portion being substantially and consistently impermeable to air and having a substantially and consistently smooth surface adapted to not retain water, the strip portions defining a web-carrying portion of the fabric therebetween, the web-carrying portion being adapted such that the wet paper web supported thereby extends over an entire width thereof, whereby the web-carrying portion is configured to allow air directed thereat to flow therethrough, exclusively of the strip portions, such that the wet paper web supported only by the web-carrying portion is exposed to the air, the width of the web-carrying portion between the strip portions thereby defining a width of the wet paper web being processed.
Still another aspect of the present invention comprises a composite fabric for through air drying, wherein such a composite fabric includes a fabric body fabricated from a first material and having a first side portion and a second side portion, wherein the first side portion is fabricated from a second material.
That is, another aspect comprises:
A composite fabric for through air drying comprising: a fabric body fabricated from a first material and having a first side portion and a second side portion, wherein the first side portion is fabricated from a second material.
Embodiments of the present invention thus address the needs identified above and provide significant advantages as further discussed herein.
Having thus described the invention in general terms, reference will now be made to the accompanying drawings, which are not necessarily drawn to scale, and wherein:
The present invention now will be described more fully hereinafter with reference to the accompanying drawings, in which some, but not all embodiments of the inventions are shown. indeed, these inventions may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein; rather, these embodiments are provided so that this disclosure will satisfy applicable legal requirements. Like numbers refer to like elements throughout.
On the basis of the exemplary TAD papermaking machine 25 shown in
In one embodiment, the strip portions 250 may be formed by applying a self-leveling filler substance to the drying fabric 100. For example, the filler substance (not shown) may be applied as a liquid to the woven material of the fabric 100. Upon application, the filler substance fills the woven structure of the fabric 100 over the width and length of each strip portion 250 and then sets into a flexible solid having a substantially and consistently smooth surface. That is, the filler substance may comprise, for example, an epoxy material or a silicone material that, when applied to the drying fabric 100 as a liquid, “self-levels” or becomes smooth as the filler substance sets into a flexible solid. in other instances, the woven thin polymeric threads forming the drying fabric 100 may be exposed to a combination of pressure and heat so as to “melt” the polymeric threads, which then re-form as an impermeable polymeric sheet upon removal of the pressure/heat. Such a process applied to the drying fabric 100 along the run thereof (i.e., in the machine direction 200) at or about the opposing lateral edges of the drying fabric 100, may also result in the formation of the strip portions 250. One skilled in the art will appreciate, however, that the strip portions 250, as disclosed, may be formed in different manners consistent with the spirit and scope of the present invention.
The strip portions 250 are also desirably consistent in width, thickness, cross-sectional shape, and the like, with substantially consistent laterally inward edges and a substantially consistent lateral spacing therebetween. In one instance (i.e., an inward flow TAD as shown, for example, in
The strip portions 250 may be, for example, at least about 2.5 cm wide to ensure that the paper web 75 does not extend across the width thereof. In some instances, each strip portion 250 may desirably have a width of about 13 cm. Further, the formed strip portions 250 may be thicker than, thinner than, or substantially the same thickness as, the woven structure of the fabric 100. In addition, the strip portions 250 may, but do not necessarily, define the opposing lateral edges 225 of the fabric 100. That is, portions of the woven structure of the fabric 100 may extend laterally outward of either or both of the strip portions 250. The strip portions 250 also define a web-carrying portion 275 of the drying fabric 100 therebetween. The width of the web-carrying portion 275 may vary depending on many factors such as, for example, the requirements of a particular product to be formed from the paper web 75. That is, the web-carrying portion 275 is particularly adapted to carry the paper web 75 for drying. Common widths of the web-carrying portion 275 may vary, for example, from about 50 cm to about 600 cm. Because of the single, substantially consistent, permeability of the woven material forming the web-carrying portion 275 of the fabric 100, the wet paper web 75 supported by the web-carrying portion 275 can extend over the entire width thereof. As such, the web-carrying portion 275 of the fabric 100 is configured to allow air directed thereat by the TAD 125 to flow therethrough, exclusively of the strip portions 250. In this manner, the wet paper web 75 supported only by the web-carrying portion 275 is dried in the TAD 125, wherein the width of the web-carrying portion 275, between the strip portions 250, defines a width of the wet paper web 75 being dried thereon.
The fabric 100 thus configured with the spaced-apart strip portions 250 to define the web-carrying portion 275 therebetween, is further configured to cooperate with the TAD 125 to form a system for drying a wet paper web 75. As shown in
The fabric 100 is configured to withstand a temperature of at least about 120° C. and, in some instances, a temperature of at least about 280° C., without premature degradation. As such, the fabric 100 is configured to withstand the heated air flowing between the hood 175 and the roll 150 of the TAD 125, and the strip portions 250 are sufficiently flexible and elastic to withstand continuous travel/stretching when running about the roll 150 during the papermaking process. The strip portions 250 are also sufficiently durable to withstand fabric, cleaning processes such as, for example, through a water spray nozzle cleaning process, without affecting the characteristics thereof as discussed herein. Because the strip portions 250 cover the gap 300, the heated air flowing in the TAD 125 is directed only through the web-carrying portion 275 of the fabric 100 (without using deckle bands), and therefore makes more efficient use of the air for drying the paper web 75. That is, since the web-carrying portion 275 is configured for the width of the paper web 75, and the paper web 75 extends over the entire width of the web carrying portion 275, substantially all of the air flowing through the TAD 12.5 flows through both the web-carrying portion 275 and the paper web 75, to dry the paper web 75. Further, the web-carrying portion 275 will be cooled by evaporation of the water within the paper web 75, thereby reducing or minimizing premature degradation of the fabric 100, as compared to the heated air flowing through portions of the fabric 100 not covered by the paper web 75 (i.e., in previous configurations using decide bands).
The TAD 125 configured with the fabric 100 having the laterally-spaced strip portions 250, as discussed, thus protects the lateral edges 225 of the fabric 100 from having hot TAD supply air flowing therethrough by eliminating the gap 300 between lateral edges of the paper web 75 and the edge portions 160 of the roll 150, through which hot air previously passed in TADs using conventional deckle bands. In this manner, the service life of the fabric 100 may be increased by minimizing or eliminating fabric degradation in the gap 300, while allowing higher temperatures (i.e., over about 200° C.) of the supply air in the TAD 125 to be utilized. The increased efficiency and/or production capacity realized by more effective use of the drying air, in addition to the faster drying realized by the higher supply air temperatures, thus provide an advantageous system for drying a wet paper web 75. Since deckle bands are eliminated, previous shortcomings such as, for example, machine start-up issues with temporary deckle bands, shutdown after initial start-up for “permanent” deckle band installation, corrosion of the roll associated with decide bands, and cleaning issues associated with the TAD roll 150, are also substantially eliminated. In addition, since the gap 300 is also eliminated by the strip portions 250 of the fabric 100, the need for gap protection measures such as, for example, air knife edge cooling and water spray edge protection, are also eliminated. As such, the system requires less equipment, and is thus less costly and less maintenance-intensive.
Another aspect of the fabric 100 having the laterally-spaced strip portions 250 is the capability of determining a width of a paper web 75 being produced. As previously discussed, the paper web 75 may be initially formed on a forming wire 50, where at least some of the water from the initially-formed paper web 75 drains through the forming wire 50. The wet paper web 75 must then be transferred to the fabric 100 for drying in the TAD 125. In order to accomplish the transfer, the fabric 100 is typically configured to run adjacent to the forming wire 50 (as shown in
The forming wire 50 of the papermaking machine 25, as discussed, may be one of the forming wires of a “twin wire former.” For example, as shown in
Further, as shown in
Downstream of the wire section, the wet end 550 may further comprise a structuring section 600, extending from the wire section to the drying section 650. The structuring section 600 comprises the structuring fabric 100 running in a dosed loop around a plurality of guide rolls (accordingly, the structuring fabric 100 may be other open-structure fabrics besides a TAD fabric). A transfer box 605 is arranged inside the loop of the fabric 100 for facilitating transfer of the web 75 from the wire section to the structuring section 600 by bringing the fabric 100 against the inner forming wire 50 wherein the suction through the fabric 100 from the transfer box 605 picks up the web 75 from the inner forming wire 50. After the transfer box 605, the web 75 is carried by the structuring fabric 100 through the structuring section 600 comprising at least one dewatering unit at least one dewatering member or device facing towards the free side of the web 75). The dewatering unit may comprise, for example, a steam box 615 being arranged outside the loop of the fabric 100 and facing towards the free side of the web 75, and a suction box 620 arranged inside the loop of the fabric 100 opposite to and/or downstream of the steam box 615. The steam box 615 serves to raise the temperature of the web 75 and the water therein, which increases the dewatering capacity of the subsequent suction box 620 by reducing the viscosity of the water. In the alternative, the dewatering members or devices in the dewatering unit can, for example, heat the web 75 using infrared radiation or hot air. A smooth and solid transfer roll 655 is arranged inside the loop of the fabric 100 for transferring the web 75 from the fabric 100 to a hot drying surface of the drying section 650 by forming a transfer nip 665 for the web 75. In some instances, a Yankee dryer 670 having an associated hood may provide the hot drying surface for drying the web 75, whereafter the web 75 is removed from the drying surface, for instance, by a creping doctor.
In accordance with embodiments of the present invention, the fabric 100 configured with the laterally-spaced strip portions 250 controls or limits the effective area of the applied suction from the suction device 325 (as well as the suction box 585, the transfer box 605, and the suction box 620, and such an effect will be apparent to one skilled in the art). In such instances, the suction is applied through the web-carrying portion 275 to draw only the desired width of the paper web 75 to the drying fabric 100, without requiring edge trimming, to ensure a clean separation of the trimmed paper web 75 from the excised edge portions. That is, a full width paper web, as formed on the forming wire 50 enters the pickup location at between about 10% to about 40% dryness, wherein the pickup suction draws a medial portion of the wet paper web 75, equal to the width of the web-carrying portion 275, from the forming wire 50 to the web-carrying portion 275 of the TAD fabric 100. However, one skilled in the art will appreciate that the dryness of the wet paper web 75, upon transfer to the fabric 100, may vary. The strip portions 250 prevent the outer edge portions of the formed paper web 75 from being exposed to the pickup suction. As such, with a certain degree of adhesion between the outer edge portions of the paper web 75 and the forming wire 50, and with no exposure to the pickup suction because of the strip portions 250 of the drying fabric 100, the outer edge portions of the paper web 75 remain on the forming wire, thereby essentially trimming the formed paper web 75 and creating uniform lateral edges of the paper web 75. Further, the width of the paper web 75 transferred to the drying fabric 100 will be equal to the width of the web-carrying portion 275 of the fabric 100. In addition, the substantially and consistently smooth surface of each strip portion 250 reduces the propensity of the strip portions 250 to retain water thereon and as such, reduces or eliminates the likelihood of the trimmed edge portions of the paper web 75 adhering to the strip portions 250 and separating from the forming wire 50. As such, the lateral edges of the wet paper web 75 are trimmed to realize a desired width paper web 75, without requiring extraneous edge trimming equipment, thereby realizing cost savings and efficiencies in terms of less equipment, less maintenance, less required energy, and no required fresh water supply over previous edge trimming systems. Further, “inner” edge trimming (i.e., a second edge trimming process to determine the desired width of the finally dried paper web 75) requirements may also be reduced or eliminated, thereby reducing or eliminating re-pulping of dry trimmings as a result.
Because the fabric 100 (having the laterally-spaced strip portions 250) itself, in combination with the pickup suction, trims the edges of the paper web 75 received from the forming wire 50, the trimmed paper web 75 extends across the entire width of the web-carrying portion 275 of the fabric 100. As a result of the paper web 75 extending across the entire width of the web-carrying portion 275, the fabric gap 300 is eliminated as an airflow path in the TAT) 125. Water evaporation from the paper web 75 in the TAD 125 thus protects the web-carrying portion 275 of the fabric 100 from the heated air in the TAD 125, while the strip portions 250 of the fabric 100 may also reduce convective heat transfer. Because portions (i.e., the gap 300) of the fabric 100 are no longer exposed to unacceptable temperature, levels of the heated air in the TAD 125, premature degradation of the fabric 100 is avoided, and, in some instances, allows higher temperatures of the supply air in the TAD 125 to be utilized without a significant risk of damage to the fabric 100.
The fabric 100 employing the laterally-spaced strip portions 250 may also simplify and/or facilitate other processes or processing of the paper web 75 within the papermaking machine 25. For example, in instances where a molding device 350 is implemented, the fabric 100 thus configured may simplify the set up of the molding device 350 for affecting the appropriate width of the paper web 75 (i.e., eliminate requirements for deckles associated with the molding box). As such, embodiments of the present invention may eliminate edge trimming systems, as well as decide requirements for the suction device 325, the molding box 350, and/or the TAD roll 150, while also facilitating alignment of the components of the papermaking machine 25. Further advantages are realized in time savings associated with aligning deckles, reduced risk for poor quality of the dried, paper web 75 because of wet or damaged lateral edges, and more efficient drying of the paper web 75 (since no supply air bypasses the paper web about the gap 300), in addition to overall energy savings. Still other advantages may be realized in instances where the desired width of the paper web 75 is changed. In such instances, the width of the paper web 75 may be readily changed by altering the lateral spacing of the strip portions 250, which can be accomplished by changing the fabric 100 to one having the appropriate lateral spacing of the strip portions 250. That is, a first fabric 100 having a first width of the web-carrying portion 275 is changed to a second fabric 100 having a second width of the web-carrying portion 275, wherein the widths of the web-carrying portions 275 are different, with both widths being less than the width of the formed paper web 75. Otherwise, converting a papermaking machine to produce a paper web 75 of a different width may involve changing the width of the parent roll (i.e., by adjusting the lateral spacing of an edge trimming system). Different width products may be encountered, for example, in bath product vs. towel product, which are often made on the same papermaking machine 25. Optimizing the width of the paper web 75 for each different product may thus increase drying efficiency, while lowering costs.
Another aspect of the present invention comprises a composite fabric 700 as shown in a partial plan view in
In the composite fabric 700, the first side portion 720 is woven to the central fabric portion 710 along a first side edge 760. The second fabric side portion 730 is woven to the central fabric portion 710 along a second side edge 770. The second side edge 770 is opposite the first side edge 760. The first and second fabric side portions 720,730 can be woven to the central fabric body 710. This weaving of the first and second fabric side portions 720,730 to the central fabric body 710 is preferably performed on the same loom on which the central fabric body was woven. There is no requirement that the first fabric side portion 720 have the same weave pattern as the central fabric portion 710 or the second fabric side portion 730. In one embodiment, the first and second fabric portions 720,730 have the same weave pattern. Additionally, the first and second fabric portions 720,730 may have the same weave pattern as the central fabric portion 710.
Still further, the first and second fabric side portions 720,730 can be subjected to the same processing as the central fabric portion 710. For example, heat setting, stretching, coating, and the like. When a coating is utilized, the coating, when compared to a composite fabric without the coating, has at least one of enhanced release properties, enhanced wear properties and enhanced thermal stability. The material used for the central fabric portion 710 of the composite fabric 700 is preferably at least one of polyester and polyethylenepterathalate (PET). The material used for the first fabric side portion 720 and/or the second fabric side portion 730 is at least one of polyphenylenesulfide (PPS), polyetheretherketone (PEEK), high temperature and hydrolysis resistant polymers, blends using PPS, blends using PEEK, alloys of PPS, alloys of PEEK, and high temperature nylon. The high temperature nylon is at least one of a variant of nylon 66 and an aromatic nylon. Additionally, the diameter of first fabric side portion fibers 780 used for the first fabric side portion 720, and the diameter of second fabric side portion fibers 790 used for the second fabric side portion 730 can be substantially the same as the diameter of the central fabric portion fibers 800 used for the central fabric portion 710. When the first (and second) side portion 720 is woven to the fabric body 710, it is woven in the same plane. It is preferred that the fabric body 710 and the first (and second) side portion 720 have substantially the same CFM throughput. However, depending on the design parameters, the CFM throughput of the first (and second) side portion 720 can be different from the fabric body 710, or may be different from the second side portion 730. Additionally, it is preferred that there is a smooth transition between the main portion 710 of the fabric and the side portions 720,730. The size of the first and second fabric side portions 720,730 is predetermined and can be based upon the size of the paper web. In one embodiment, the width of each of the fabric side portions 720,730 is approximately 10-60 cm when measured in the weft direction, preferably approximately 20-40 cm.
Many modifications and other embodiments of the inventions set forth herein will come to mind to one skilled in the art to which these inventions pertain having the benefit of the teachings presented in the foregoing descriptions and the associated drawings. For example, a papermaking clothing as disclosed herein may be implemented in other paper web forming systems and processes such as, for example, a vacuum dewatering system and process. Therefore, it is to be understood that the inventions are not to be limited to the specific embodiments (i.e., TAD papermaking machines or non-TAD papermaking machines) disclosed and that modifications and other embodiments (i.e., for other papermaking processes) are intended to be included, within the scope of the appended claims. Although specific terms are employed herein, they are used in a generic and descriptive sense only and not for purposes of limitation
Claims
1. A method of determining a width of a paper web, comprising: transporting a wet paper web on a forming wire in a machine direction toward an endless fabric having a permeable web-carrying portion, the wet paper web being formed on the forming wire so as to be wider than the permeable web-carrying portion of the fabric, the fabric being formed only from a woven material so as to have a single, substantially consistent, permeability, the fabric further including opposed lateral edges and a pair of laterally spaced apart strip portions extending along the fabric in the machine direction, each strip portion being substantially and consistently impermeable and having a substantially and consistently smooth surface adapted to not retain water, the impermeable strip portions thereby defining the permeable web-carrying portion of the fabric therebetween; and engaging the wet paper web with the fabric such that only the permeable web-carrying portion of the fabric receives the wet paper web, exclusively of the impermeable strip portions, thereby trimming the wet paper web to the width of the permeable web-carrying portion such that the wet paper web extends over an entire width of the permeable web-carrying portion.
2. A method according to claim 1 further comprising directing air toward the fabric, the permeable web-carrying portion thereof being configured to allow the air to flow therethrough, exclusively of the impermeable strip portions, such that the wet paper web carried only by the permeable web-carrying portion is at least one of dried and dewatered, the width of the permeable web-carrying portion between the impermeable strip portions thereby defining a width of the wet paper web being at least one of dried and dewatered on the drying fabric.
3. A method according to claim 1 further comprising imparting suction through the permeable web-carrying portion of the fabric with a suction device operably engaged with the fabric, such that the wet paper web having the width of the permeable web-carrying portion is received by the fabric from the forming wire.
4. A method of changing a width of a paper web within a single papermaking machine, comprising: transporting a wet paper web on a forming wire in a machine direction toward a first endless fabric having a first permeable web-carrying portion, the wet paper web being formed on the forming wire so as to be wider than the first permeable web-carrying portion of the first fabric, the first fabric being formed only from a woven material so as to have a single, substantially consistent, permeability, the first fabric further including a pair of laterally spaced apart first strip portions extending along the first fabric in the machine direction, each of the first strip portions being substantially and consistently impermeable and having a substantially and consistently smooth surface adapted to not retain water, the first impermeable strip portions thereby defining the first permeable web-carrying portion of the first fabric, therebetween; engaging the wet paper web transported by the forming wire with the first fabric such that the first permeable web-carrying portion of the first fabric receives the wet paper web and such that the wet paper web extends over an entire width of the first permeable web-carrying portion, exclusively of the first impermeable strip portions, so as to trim the wet paper web to the width of the first permeable web-carrying portion; replacing the first fabric with a second endless fabric formed only from a woven material so as to have a single, substantially consistent, permeability, the second fabric further including a pair of laterally spaced apart second strip portions extending along the second fabric in the machine direction, each of the second strip portions being substantially and consistently impermeable and having a substantially and consistently smooth surface adapted to not retain water, the second impermeable strip portions thereby defining a second permeable web-carrying portion of the second fabric therebetween; and engaging the wet paper web transported by the forming wire with the second fabric such that the second permeable web-carrying portion of the second fabric receives the wet paper web and such that the wet paper web extends over an entire width of the permeable second web-carrying portion, exclusively of the second impermeable strip portions, the second permeable web-carrying portion having a different width than the first permeable web-carrying portion and being narrower than the wet paper web formed on the forming wire, so as to trim the wet paper web to the width of the second permeable web-carrying portion.
5. A method according to claim 4 further comprising directing air toward one of the first and second fabrics, the permeable web-carrying portion thereof being configured to allow the air to flow therethrough, exclusively of the corresponding impermeable strip portions, such that the wet paper web carried only by the permeable web-carrying portion of the one of the first and second fabrics is at least one of dried and dewatered, the width of the permeable web-carrying portion between the corresponding impermeable strip portions thereby defining a width of the wet paper web being at least one of dried and dewatered on the one of the first and second fabrics.
6. A method according to claim 4 further comprising imparting suction through one of the first and second permeable web-carrying portions with a suction device operably engaged with the corresponding fabric, such that the wet paper web having the width of the one of the first and second permeable web-carrying portions is received by the corresponding fabric from the forming wire.
7. A method of forming a papermaking clothing adapted to support a wet paper web for drying or dewatering, from an endless fabric formed only from a woven material so as to have a single, substantially consistent, permeability, the fabric defining a machine direction and having opposed lateral edges, said method comprising: applying a self-leveling filler substance to the fabric at laterally spaced apart positions so as to form a pair of laterally spaced apart strip portions extending along the fabric in the machine direction; and allowing the self-leveling filler substance to set such that each strip portion becomes substantially and consistently impermeable to air and forms a substantially and consistently smooth surface adapted to not retain water, whereby the strip portions define a web-carrying portion of the fabric therebetween.
8. A method according to claim 7 wherein applying the self-leveling filler substance further comprises applying the self-leveling filler substance to the fabric as a liquid such that the self-leveling filler substance solidifies following application.
9. A method of forming a papermaking clothing adapted to support a wet paper web for drying or dewatering, from an endless fabric formed only from a woven material so as to have a single, substantially consistent, permeability, the fabric defining a machine direction and having opposed lateral edges, said method comprising: applying heat to the fabric at laterally spaced apart positions, the heat being configured to cause the fabric at the laterally spaced apart positions to attain a material flow temperature; and applying a pressure to the fabric at the laterally spaced apart positions, substantially simultaneously with heating the fabric thereat to the material flow temperature, so as to form a pair of laterally spaced apart strip portions extending along the fabric in the machine direction, each strip portion being substantially and consistently impermeable to air and forming a substantially and consistently smooth surface adapted to not retain water, whereby the strip portions define a web-carrying portion of the fabric therebetween.
10. A composite fabric for through air drying comprising: a fabric body fabricated from a first material and having a first side portion and a second side portion, wherein the first side portion is fabricated from a second material.
11. The composite fabric of claim 10, wherein the second side portion is fabricated using a third material.
12. The composite fabric of claim 11, wherein the second material and the third material are the same material.
13. The composite fabric of claim 10, wherein the first side portion is woven on the same loom as the fabric body.
14. The composite fabric of claim 10, wherein the first side portion has the same pattern as the fabric body.
15. The composite fabric of claim 10, wherein the first side portion has the same processing as the fabric body.
16. The composite fabric of claim 10, further comprising a coating.
17. The composite fabric of claim 16, wherein the coating, when compared to the composite fabric, has at least one of enhanced release properties, enhanced wear properties and enhanced thermal stability.
18. The composite fabric, of claim 10, wherein the second material is at least one of polyphenylenesulfide (PPS), polyetheretherketone (PEEK), high temperature and hydrolysis resistant polymers, blends using PPS, blends using PEEK, alloys of PPS alloys of PEEK, and high temperature nylon.
19. The composite fabric of claim 18, wherein the high temperature nylon is at least one of a variant of nylon and an aromatic nylon.
20. The composite fabric of claim 10, wherein the first material is at least one of polyester and polyp (PET).
21. The composite fabric of claim 10, wherein the diameter of the second material is substantially the same as the diameter of the first material.
22. The composite fabric of claim 10, wherein the first side portion has a plane in the same plane as the fabric body.
23. The composite fabric of claim 10, wherein the fabric body and the first side portion have substantially the same CFM throughput.
24. The composite fabric of claim 10, wherein the fabric body and the first side portion have different CFM throughput.
25. The composite fabric of claim 10, wherein the first side portion has a width of approximately 10-50 cm in a weft direction.
26. The composite fabric of claim 10, wherein the second side portion has a width of approximately 10-50 cm in a weft direction.
Type: Application
Filed: May 21, 2014
Publication Date: Sep 11, 2014
Applicant: Albany International Corp. (Albany, NY)
Inventors: Joseph R. Pilsbury (Westbrook, ME), Stacie R. Dede (Hammaro)
Application Number: 14/283,545
International Classification: D21F 1/00 (20060101); D21F 7/00 (20060101);